WO2003012856A2

WO2003012856A2 - Method for hermetically encapsulating a component

Info

Publication number: WO2003012856A2
Application number: PCT/DE2002/002188
Authority: WO
Inventors: Alois Stelzl; Hans Krüger; Gregor Feiertag; Ernst Christl
Original assignee: Epcos Ag
Priority date: 2001-07-27
Filing date: 2002-06-14
Publication date: 2003-02-13
Also published as: JP4299126B2; WO2003012856A3; US20040237299A1; EP1412974B1; EP1412974A2; US7552532B2; DE10136743B4; JP2004537178A; DE10136743A1

Abstract

The invention relates to a method for hermetically encapsulating a component (1) that is mounted in flip-chip design on a support (4). The inventive method is characterized by first covering the component with a film (8) that closely rests on the component and the support, then structuring the film, and providing thereon a hermetically sealing layer (14), especially a metal layer, which seals up with the support.

Description

description

Process for the hermetic encapsulation of a component

A method for the hermetic encapsulation of a component is known, for example, from WO 99/43084. There components, in particular surface wave components, are applied to a carrier provided with solderable connection surfaces using flip-chip technology. In this case, the component is soldered onto the carrier via bumps (solder balls) in such a short distance that the surface with the component structures faces the carrier. For the hermetic encapsulation of the components located on the carrier, these are finally covered with a metal foil or a metal-coated plastic film on the carrier from the back and glued or laminated. The film closes tightly with the carrier between the components applied to the carrier, so that a hermetic encapsulation is created for the component structures. It is also proposed that the encapsulation by pressing or casting, z. B. to further stabilize with epoxy resin and to further seal hermetically. The components can then be separated by separating the carrier plate.

It has been found that the use of a metal foil as well as the use of a metal-coated plastic foil for direct application to the rear of the component is fraught with problems and can lead to components whose hermetic sealing is unsatisfactory.

It is therefore an object of the present invention to provide a method for producing a hermetic encapsulation which is simple to carry out and leads in a secure manner to a hermetically encapsulated component.

This object is achieved according to the invention by a method with the features of claim 1. Advantageous design The claims of the inventions and advantageous uses of the invention can be found in further claims.

The invention proposes to first cover a component applied in a flip-chip construction on a carrier with a first film, to connect this in the edge area around the component to the surface of the carrier, to subsequently structure the film, and as a last step to cover a hermetically sealing layer to apply the film so that it is hermetically sealed to the carrier outside the edge area.

By separating the encapsulation into two layers to be applied independently of one another, it is possible to optimize the two steps independently of one another. The first step can be adapted so that the film, in cooperation with the application conditions, lies tightly on the back of the component and in the edge area around the component on the carrier. The structuring of the film takes place in an intermediate step, in particular a dimensioning of the covering film taking place, which defines the size of the encapsulated component. Furthermore, when structuring outside the edge area, the area of the carrier is exposed, so that the hermetically sealing layer can come into contact with the carrier in order to ensure a tight seal with the carrier.

The film, which already tightly encloses the component and lies on the carrier, enables the hermetic

Apply layer in a variety of different processes. Since the component is covered under the film, isotropic layer production processes, wet chemical processes, gas or steam can also be used, as can plasma processes. With a suitably selected film, the hermetically sealing layer can also be applied as a melt. In comparison to the known method, in which for example, a metal-coated plastic film is used as the sole cover, the tightness is considerably improved in the method according to the invention by the two layers or films to be applied independently of one another. While the application of the film can be optimized for positive locking, the second layer can be optimized for tightness.

According to the invention, a form-fitting application of the film to the chip back and the carrier is achieved in particular with a thermoplastic film. This can be softened when applied at elevated temperature and laminated under pressure on the back of the chip and the surface of the carrier. The positive application can be supported by applying a vacuum between the film and the carrier.

Particularly suitable as thermoplastic material for the film are those materials which are resistant to contact with live metal surfaces, which are resistant to corrosion and aging, show no outgassing, have high temperature resistance and / or have sufficient adhesion to the carrier material. A further criterion is the laminatability of the corresponding film, which, when softened and laminated while being applied to the chip and the carrier, must not receive any damage and in particular cracks or holes. Films made of polyamide and polyimide, which have a high thermal stability, are particularly suitable.

Other suitable materials for the film are thermosets and reactive resins, for example epoxy resins. Because of the limited laminating properties of cured thermosets and reactive resins, films made from such materials are preferably used in an uncured or at least not fully cured state. For reactive resins, for example, the technique of curtain casting is suitable, in which a liquid polymer, for example a reactive resin thin film is produced by casting on a substrate and then cured on the substrate. With a suitably set consistency of the reaction resin, such a layer can be handled like a film.

Since the film can be applied to the chip with mechanical pressure and the flip-chip connection can be deformed, a material of high strength is advantageously chosen for the bumps which shows no mechanical deformation when the films are applied. In particular, SnAg,

SnAgCu, SnCu, Au or conductive adhesive suitable. This avoids undesirable and uncontrollable changes in the geometry of the component during the method.

Various techniques are suitable for structuring the applied film. For example, it is possible to use photolithography to define and protect the areas of the film which are to remain on the carrier or the component. A wet chemical or a plasma etching process can then be used as the structuring agent.

However, it is also possible to structure the film directly, for example by means of mechanical layer removal processes or by means of a laser. The structuring takes place in such a way that the film is retained in the edge region of a defined width around the chip, in which it also lies firmly on the carrier. The function of the film as a seal of the component with respect to the application method of the hermetically sealing layer or as a component of the entire encapsulation is thus maintained or guaranteed. The film is then removed outside the edge area at least to the extent that a sufficiently wide surface area of the carrier is exposed in a ring shape around the edge region in order to ensure that the hermetically sealed layer to be applied is sealed with the carrier.

In a further embodiment of the invention, it is possible not to have the film in a sufficiently wide strip, but to be removed in the area of at least two substantially narrower strips which enclose the edge area at a small distance from it. In this way, a hermetic seal of the hermetically sealed layer to the carrier is made possible in the contact area on a much smaller area than when only one strip is used. This reduces the surface area on the carrier required for the hermetic encapsulation of the component and thus also the size of the entire component. It is sufficient, for example, the strips with a width and in one

To form a distance from each other, which corresponds approximately to the thickness of the film. While a relatively large strip width is provided for a single contact strip for the hermetic layer to the support, z. B. two strip-shaped contact areas only widths of about 35 microns, for example, required, which requires less space. If necessary, it is possible to remove the film in the region of more than two parallel strips in order to further increase the tightness of the hermetic layer or the tight seal of the hermetic layer with respect to the carrier. A further improved tightness of the entire encapsulation is thus obtained.

In a further embodiment of the invention, in order to increase the tightness of the encapsulation, in addition to the surface of the carrier, an area of the chip surface is also exposed, in particular on the back or all around on the side surfaces, in order to ensure tight contact of the hermetically sealing layer possible directly with the chip. Here too, the film can be partially removed in a strip-shaped region with the aid of a laser technique, the strip either running on the lateral outer surfaces of the chip and being closed in a ring or being arranged on the back of the chip and running in the vicinity of the outer edges of the chip , However, it is also possible to use part or all of the back of the chip with the structuring used. drive, for example, using a photolithography technique.

In a further embodiment of the invention, the chip on the back can be provided with at least one partial metallization, but preferably metallized over the entire surface. In this way, a good heat-conducting connection between the chip and the hermetically sealing layer can be produced, which is not necessarily guaranteed by the film used alone. The rear side metallization can also be connected to the component structures on the front side of the chip facing the surface of the carrier. In this way, there is an additional connection possibility for the component structures on the back of the chip.

A metal layer is preferably applied as the hermetically sealing layer. This can in particular be produced in a multi-stage process, in which case a base metallization is first applied to the entire surface of the film and the surface of the carrier exposed in the contact area, which is reinforced in a subsequent step. A sputtering process or an electroless metal deposition process or a combination of both processes is preferably used to produce a basic metallization. For example, a base metallization can advantageously be produced by sputtering copper and / or nickel. Copper deposition baths in particular are known for electroless deposition on non-conductive surfaces such as, for example, the film. The currentless stripping process also has the advantage that it also ensures metal deposition at those locations on the component that are not accessible for sputtering. At such points, electrically non-conductive areas could arise with other methods, which then can no longer be reinforced. These points would then be potential leaks for the component and are avoided by using electroless metal deposition. The electroless metal deposition is preferably carried out after the Sputtering of a basic metallization is carried out, since in particular a sputtered titanium / copper layer has advantages with regard to good adhesion to the film and largely prevents diffusion of moisture into the interior of the component during the subsequent wet chemical or electrochemical process.

Galvanic processes are particularly suitable for reinforcing the basic metallization, especially if there is already a continuous and dense basic metallization. The deposition of copper is particularly suitable for galvanic reinforcement, which is then covered with a thinner layer of a corrosion-inhibiting metal, for example with nickel or a noble metal. However, it is also possible to generate the metal layer by electroless deposition either directly on the component or on the base metallization to the desired thickness. However, it is also possible to produce the metal layer with or without base metallization by vapor deposition of a metal or by bringing the component into contact with a metal melt. Combinations of the specified processes are also suitable.

The thickness of the metal layer used as the hermetically sealing layer is selected depending on the properties desired. Adequate tightness is obtained with just a few μm. If the hermetically sealing layer or the metal layer is used for HF shielding of electronic components, in particular for shielding HF frequencies working components, then a higher thickness can be used to achieve the desired HF shielding against external influences or for shielding against radiation from the component to be required. Metal layers with a thickness of approx. 3 to 14 μm are generally suitable. If the metal layer is used for HF shielding, it is preferably connected to ground. This can be done in such a way that a metallization is provided on the carrier in the contact area which is in direct contact with the metal layer and is connected to the ground connection of the component. For example, this metallization can be contacted by a through-contact through the carrier, which in turn is electrically conductively connected to ground connections on the underside of the carrier. In a further embodiment of the invention, the metal layer is connected both to an electrical connection on the carrier and to the back of the chip. For this purpose, it is necessary to remove the film from the back of the chip at least in the area of this contact during structuring or in a separate step, or to expose the back of the chip there before the hermetically sealing layer is applied. For this purpose, a chip is used which has a metallization on the back of the chip. The electrical connection of this metallization via the metal layer of the hermetically sealing layer with an electrical component connection, for example on the underside of the carrier, can then be used for electrical tuning of the component, in particular for electrical tuning of a component working with acoustic waves, in particular a filter.

In a further embodiment of the invention, a layer is applied directly on the back of the chip before or after the application of the film, if in the latter case the back of the chip is exposed during structuring, which is suitable for damping bulk waves, the component in this Case is a component working with surface acoustic waves. Such a bulk wave damping layer is acoustically adapted to the material of the chip and has a suitable E-module for damping. Such materials are well known. Furthermore, the application of inorganic and ceramic materials, for example silicon dioxide, glass or silicon carbide, is also suitable for producing a hermetically sealing layer. In particular, materials based on silicon dioxide and in particular glasses can be produced in a number of thin-film processes or applied to any surface. Glasses have the advantage that, due to their low melting point, they can be softened and compressed by means of a tempering step. The softening also results in a flow and thus a good surface-conforming surface coverage.

For a further embodiment of the encapsulation according to the invention, it is proposed to apply a plastic cover, a so-called glob top, to the carrier above the hermetically sealing layer. This is applied to the carrier over the hermetically sealing layer in an initially liquid but mostly viscous form, preferably up to a height such that a uniform layer thickness is obtained over the carrier or a flat surface of the entire component. Reaction resins are particularly suitable as glob top masking compounds. However, it is also possible to use thermoplastic molding compounds. While the reaction resins can also be dripped or poured on, a suitable injection mold is required to apply molding compounds.

A mechanically and electrically adapted material or a combination of such materials is suitable for the carrier used according to the invention. The carrier material preferably has sufficient mechanical strength and is also hermetically sealed against gases and moisture. A carrier with a multilayer structure is preferably used, which has metallizations on the surface for contacting the component via bumps, and that on the back

Has connection metallizations for connecting to a circuit board, especially in SMD technology. Between two Layers can be provided with wiring levels, the connection between the different levels or the intermediate levels and the top and bottom of the carrier being made via vias. To increase the tightness, all plated-through holes from the top to the bottom of the carrier are not continuous and at least laterally offset from one another. For the carrier a plurality of materials are suitable, for example, alumina, glass, HTCC, LTCC or organic carriers such as PCB or foil materials such as Kapton ^® or Mylar ^®. In order to achieve reliable contacting with increasing miniaturization of the components, in particular when flipchip bonding the component to the carrier, an LTCC ceramic is advantageous which, due to its low shrinkage during firing, has a precisely predetermined geometry of the metallizations. Carriers made of organic materials can also be manufactured with an exact geometry, but they are less impervious to the environment.

A carrier can be used for connection to exactly one chip and is then preferably dimensioned in accordance with the chip dimensions. However, it is also possible to provide a carrier for receiving several chips, which then has correspondingly separate or separable metallizations for connecting the individual chips. After the chips have been applied to the carrier by means of flip-chip technology, the encapsulation method according to the invention can be carried out at once for all components or for the entire carrier. Finally, the carrier can then be separated into the individual chips by separating the carrier between the chips. This can be done for example by sawing, breaking or other separation processes.

In a further embodiment, the invention is used to encapsulate a module. In this case, the carrier represents the module substrate on which the named component is applied together with other similar or different components. The other components can be applied to the module using flip-chip technology as well as SMD technology. It is essential, however, that the entire module can be encapsulated by covering it with film, structuring the film and applying a hermetically sealing layer. LTCC ceramics are particularly suitable for producing such modules.

The method according to the invention is advantageously used for the encapsulation of surface acoustic wave components, the component structures of which on the one hand cannot be covered with additional layers, but on the other hand are particularly sensitive to corrosion and other external influences and therefore require hermetic encapsulation. In addition, the need for further miniaturization is particularly pronounced in surface wave components in order to achieve additional volume and weight savings in the preferred application in mobile telecommunications devices. With the encapsulation according to the invention, a particularly small and light packaging or encapsulation of the components, here the surface wave components, is achieved.

Another group of sensitive components that can be reliably and tightly encapsulated with the encapsulation according to the invention are sensors. It is therefore also possible to encapsulate optical and in particular optoelectronic components according to the invention. In this case, in particular translucent materials and in particular a translucent carrier are used. It is also possible for the encapsulation of optical components to keep the back of the component at least partially free of individual or all layers of the encapsulation.

The invention is described in more detail below with reference to exemplary embodiments and the associated figures. FIG. 1 shows a schematic cross section of a component bonded to a flip chip carrier

Figure 2 shows a schematic cross section of the component with the film applied over it

FIG. 3 shows the component in a schematic cross section with different strip-like structuring options

FIG. 4 shows the component in a top view after a strip-like structuring

Figure 5 shows the component in plan view after a varied structuring

FIG. 6 shows the component in a schematic cross section after this structuring

FIG. 7 shows the component after the hermetically sealing layer has been applied

FIG. 8 shows a schematic cross section of the contacting of a rear side metallization on the chip with the hermetically sealing layer

FIG. 9 shows a schematic cross section of the electrical contacting of the hermetic layer with a ground connection on the underside of the carrier

Figure 10 shows the component after the application of a glob top plastic cover

FIG. 11 shows a component with a bulk wave damping layer on the back of the chip FIG. 1 shows a schematic cross section of a chip 1, which carries component structures 2 on its underside and is designed, for example, as a surface wave component. The chip 1 is connected to metal pads on a carrier 4 via bump solder connections 3. The carrier 4 is constructed here in two layers and has multi-layer wiring. The middle metallization level 5 is used for interconnection and, if necessary, for sealing the plated-through holes 7. Via the plated-through holes 7 and the bumps 3, the component structures 2 are connected to the ones with connection metallizations 6 on the underside of the carrier. The plated-through holes 7 through a separate layer of the carrier are always laterally offset from one another, so that through-holes 4 are avoided through the entire carrier, which represent potential leaks for the hermetic encapsulation of the component.

Figure 2: A plastic film 8 is now applied over the back of the component 1 and the entire carrier 4 and laminated by increasing the temperature and under pressure onto the back of the chip 1 and the surface of the carrier 4 surrounding it. This creates a tight connection between the film 8 and the surface of the carrier 4 in an edge region 13 surrounding the chip 1.

FIG. 3 shows in a schematic cross section how strip-shaped structures 9 of the plastic film 8 are also used to expose strip-shaped regions of the carrier surface.

FIG. 4 shows a schematic plan view of the carrier 4 and the chip 1 bonded thereon and an exemplary arrangement of these strip-shaped structures 9. Leaving an edge region 13 around the chip 1, the strip-like structures 9 run parallel to the outer edge of the chip or parallel to the edge region. In the strip-like structuring, the bring hermetically sealed layer with the surface of the carrier 4 hermetically.

FIG. 3 shows further possibilities for stripe-shaped structuring 10 along the side walls of the chip 1 and structuring 11 on the back of the chip. These, individually or in combination, can also serve to bring the subsequent hermetically sealing layer into intimate (hermetic) contact with the chip body. However, sufficient hermetic coverage is achieved without these additional structures 10 and 11.

FIG. 5 shows, in a schematic plan view of the surface of the carrier and the chip 1, a further possibility for structuring the film 8. Around the edge area 13 surrounding the chip 1, the film 8 is removed in a wide and, for example, 200 μm wide strip.

FIG. 6 shows the component according to this structuring variant in a schematic cross section. The contact strip 12 is now free of film, in contrast, the film sits tightly on the carrier 4 in the edge region 13.

A metal layer 14 is now applied as a hermetically sealing layer to the film 8 structured according to one of the methods mentioned. For this purpose, a metallic base layer is preferably first produced by sputtering on titanium and copper. This layer has a thickness of less than one μm, for example. To avoid non-metallized foil areas, the base metallization is then reinforced by electroless deposition of, for example, copper by approximately 1 to 12 μm. The electrolessly deposited metallization can then be galvanically reinforced, for example also with copper. An approximately 2 μm thick nickel layer (in particular for RF shielding) is then applied. The metallization is advantageously adapted to the thermal expansion of the carrier. As a result, ne hermetically sealed metal layer 14 is obtained, which lies well on all sides on the structured film 8 and which comes into contact with the surface of the carrier 4 in the freely structured edge 12 (contact area) or alternatively in the strip-shaped structuring 9. This contact forms a hermetic seal to the carrier 4 around the chip.

FIG. 8 shows a schematic cross section of a further embodiment of the invention, in which the chip 1 has a rear-side metallization 16 at least in parts of its rear side. When structuring the film 8, the rear side metallization 16 is at least partially exposed. In the exemplary embodiment shown, the rear side metallization 16 is exposed at point 15 in the form of dots or strips. When the hermetically sealed layer or the metal layer 14 is applied, it can come into electrically conductive contact with the rear side metallization 16 exposed there at the point 15.

FIG. 9 shows an embodiment in which the metal layer forming the hermetic layer 14 overlaps with a metallization 17 and thus makes an electrical contact. The metallization 17 is electrically conductively connected to a ground connection formed on the underside of the carrier 4. This makes it possible to connect the hermetic layer 14 to ground at freely definable edge locations, as a result of which better HF shielding of the component is achieved.

FIG. 10 shows a schematic cross section of a further embodiment of the invention of a glob top cover over the hermetically sealed layer. This plastic cover 18 is applied here at such a height that it forms a flat surface parallel to the surface of the carrier. This cover, for example made of reactive resin, leads to a further improved hermetic seal of the component against the environment. FIG. 11 shows a further embodiment of the invention in which the film 8 and the hermetic cover 14 are combined with a bulk wave damping layer 19. In the embodiment shown, the bulk wave damping layer 19 is applied to the back of the chip before the chip is applied. The possibility of removing the film in the region of the rear side above the bulk wave damping layer 19 is not shown. It is also possible to apply the volume wave damping layer 19 in the area of the rear side above the film 8 but below the hermetically sealing layer 14, for example before structuring the plastic layer.

Although the invention could only be explained on the basis of a few specific exemplary embodiments, it is of course not restricted to these. Within the scope of the invention there are further possible variations with regard to the choice of materials, the structuring or the combination of features shown only in individual figures.

Claims

claims

1. A method for producing a hermetic encapsulation for an electronic component with the steps: a) fixing and electrical contacting one on one

Chip (1) constructed component on an electrical connection surfaces (7) having carrier (4) so that the component structures (2) facing the front of the chip facing the carrier and after attachment is arranged at a clear distance from this b) covering the back of the Chips with a film (8) made of plastic so that the edges of the film overlap the chip c) tightly connecting the film (8) to the carrier (4) in the entire edge region (13) around the chip d) structuring the Film in such a way that the film is at least partially removed outside the edge area. E) Applying a hermetically sealing layer (14) over the film in such a way that the sealing layer hermetically seals with the carrier in a contact area outside the edge area (13).

2. The method according to claim 1, in which in step b) and c) a thermoplastic film (8) is used, which overlaps the chip (1) and is laminated under pressure and elevated temperature to the back of the chip and the carrier (4) ,

3. The method according to claim 1 or 2, in which in step e) a base metallization is first applied to the film (8) and the surrounding surface of the carrier (4) and this is then electrolessly and / or electrolytically reinforced.

4. The method of claim 1 or 2, in which in process step e) first a basic metallization electroless on the film (8) and the surrounding surface Before the carrier (4) is applied, it is then reinforced to the required thickness by at least one of the steps sputtering, vapor deposition, electroless deposition, electrodeposition, contacting with a molten metal or by a combination of the methods.

5. The method according to any one of claims 1-4, in which the film (8) in method step c) is removed by laser ablation in at least two strips (9) running parallel to the edge region at a small distance from one another, the surface of the carrier (4) or a metallization (17) located thereon is exposed.

6. The method of claim 5, wherein the strips (9) are formed with a width and a distance which corresponds approximately to the thickness of the film (8).

7. The method according to any one of claims 1-6 in which a metallization (16) is generated on the back of the chip (1), and in which the film (8) on the back in before the application of the hermetically sealing layer (14) Area of the metallization (16) is at least partially removed.

8. The method according to any one of claims 1-7 in which the film (8) is applied in step b) by means of curtain casting.

9. The method according to any one of claims 1-8, in which outside the edge region (13) on the carrier (4) with a ground connection of the carrier (4) connectable metallization (17) is provided, which with the hermetically sealing layer (14 ) overlaps and contacts them electrically.

10. The method according to any one of claims 1-9, in which, according to method step e), a plastic cover (18), initially in liquid form, is applied over the entire surface of the carrier (4) and the back of the chip (1) covered with the hermetic layer (14) so that the plastic cover (18 ) forms an almost flat surface after hardening.

11. The method according to claim 1-10, in which a surface wave component is used and in which an additional, substantially organic and bulk wave damping layer (19) directly on the back of the chip (1) or on the film (8) above the back ) is applied.

12. The method according to any one of claims 1-11, in which an inorganic layer is selected as the hermetically sealing layer (14), selected from Si0 ₂ , SiC or glass.

13. The method according to any one of claims 1-12, in which a photostructuring is used for structuring the film (8).

14. The method according to any one of claims 1-13, wherein the carrier (4) is a module on which further chips

(1) and / or other components are applied in the manner mentioned, contacted with the carrier and encapsulated in accordance with process steps b) to e).

15. The method according to any one of claims 1-13, in which by means of method steps a) to e) a plurality of chips (1) on a common carrier (4) are attached, contacted and encapsulated, and in which the chips are then separated by separating the common Carrier between the chips outside of said edge areas (13) are separated.

16. The method according to any one of claims 1-15, in which as the carrier (4) a particularly multi-layer plate with solderable metal coatings on the side facing the chip (1) and with these electrically connected connection metallizations (6) on the back whose base material is selected from aluminum oxide, glass, HTCC, LTCC or an organic polymer.

17. The method according to any one of claims 1-16, in which a material of high strength is selected for the bumps, which shows no mechanical deformation when the films (8) are applied.

18.Use of the method according to one of the preceding claims for the encapsulation of surface acoustic wave components.

19. Use of the method according to one of the preceding claims for encapsulating sensors.

20.Use of the method according to one of the preceding claims for the encapsulation of optical and in particular at least partially translucent components, wherein a carrier made of glass is used.